Method for injecting water into a multistage axial compressor of a gas turbine

The invention claimed is: 1. A method for injecting water into a multistage axial compressor of a gas turbine, comprising: injecting water at a plurality of points along the axial compressor; and controlling an injected water mass flow at individual injection points in accordance with ambient conditions and operating parameters of the gas turbine for creating an evened-out loading in individual stages of the axial compressor via an analysis of a meridional mean line flow with a droplet evaporation model and a model of blade erosion. 2. The method as claimed in claim 1 , wherein the injecting of the water is controlled such that more water is injected between the stages of the axial compressor than is injected at other points along the axial compressor. 3. The method as claimed in claim 2 , wherein the axial compressor has a row of variable, or variably opening, inlet guide vanes at an inlet, wherein the injecting of the water is controlled such that the water is injected upstream of the row of variable inlet guide vanes. 4. The method as claimed in claim 3 , comprising: delivering the water to the injection points by pumps; and controlling the pumps for controlling the injected water mass flow. 5. The method as claimed in claim 1 , comprising: delivering the water to the injection points by pumps; and controlling the pumps for controlling the injected water mass flow. 6. The method as claimed in claim 1 , comprising: controlling distribution of water to the individual injection points by control valves in corresponding feed lines. 7. The method of claim 1 , wherein the analysis of the meridional mean line flow with a droplet evaporation model is performed such that the meridional mean line flow is analyzed based on wet compression effects of temperature lowering and of an increase in a steam proportion to correct for density and meridional velocity; and wherein the model of blade erosion is based on experimentally verified algorithms for predicting erosion rate of blades of the axial compressor. 8. A method for injecting water into a multistage axial compressor of a gas turbine, comprising: injecting water at a plurality of points along the axial compressor; controlling an injected water mass flow at individual injection points in accordance with ambient conditions and operating parameters of the gas turbine for creating an evened-out loading in individual stages of the axial compressor; and controlling the injected water mass flow via an analysis of a meridional mean line flow with a droplet evaporation model. 9. The method as claimed in claim 8 , comprising: calculating evaporation effects blade row by blade row in the analysis; and considering wet compression effects of a temperature lowering and of an increase in steam proportion in the analysis. 10. The method as claimed in claim 9 , comprising: predicting an erosion rate with a model of blade erosion. 11. The method as claimed in claim 8 , comprising: controlling distribution of water to the individual injection points by control valves in corresponding feed lines. 12. An injection system for a multistage axial compressor of a gas turbine, comprising: a plurality of individual injectors which are arranged in series in an axial direction inside the axial compressor for injecting water into a gas passage of the axial compressor; and an injection control system configured to control a water mass flow to the individual injectors according to an analysis of a meridional mean line flow with a droplet evaporation model and a model of blade erosion. 13. The injection system as claimed in claim 12 , comprising: a gas turbine control system for the gas turbine, the injection control system being in intercommunication with the gas turbine control system. 14. The injection system as claimed in claim 13 , comprising: individual feed lines for supplying the injectors with water; and a control valve for throughflow control arranged in each individual feed line, each control valve being connected to the injection control system. 15. The injection system as claimed in claim 14 , comprising: pumps for delivering water to the injectors the pumps being connected to the injection control system. 16. The injection system as claimed in claim 12 , comprising: individual feed lines for supplying the injectors with water; and a control valve for throughflow control arranged in each individual feed line, each control valve being connected to the injection control system. 17. The injection system as claimed in claim 16 , comprising: pumps for delivering water to the injectors, the pumps being connected to the injection control system. 18. The injection system as claimed in claim 16 , wherein the axial compressor comprises: a row of variable, or variably opening, inlet guide vanes at an inlet, at least one of the injectors being arranged upstream of the row of inlet guide vanes. 19. The injection system as claimed in claim 15 , wherein the axial compressor comprises: a row of variable, or variably opening, inlet guide vanes at an inlet, at least one of the injectors being arranged upstream of the row of inlet guide vanes. 20. The injection system of claim 12 , wherein the analysis of the meridional mean line flow with the droplet evaporation model and the model of blade erosion is configured such that the droplet evaporation model is based on wet compression effects of temperature lowering and of an increase in a steam proportion to correct for density and meridional velocity and the model of blade erosion is based on experimentally verified algorithms for predicting erosion rate of blades of the axial compressor; and wherein the injection control system is configured to control the water mass flow to the individual injectors according to the analysis of a meridional mean line flow to modulate water volume that is injected so that an erosion rate for blades of the compressor is evenly distributed about multiple blade rows of the blades of the compressor.